Abstract
The effect of the substitution of Tifton hay (0, 33, 66, 100 g/100 g) for pineapple (Ananas comosus L.) stubble hay was evaluated in the characteristics of the carcasses of goats of an unknown breed (UB) in feedlot. Thirty-two bucks with an average initial live weight of 17.5±1.3 kg, at approximately 150 days of age, were housed in individual stalls provided with feeding and drinking troughs. The animals were distributed in a completely randomized design with four treatments and eight replications. There was a quadratic effect on the weights of hot carcass and cold carcass, empty body, and loin eye area. A linear increase was observed for losses by carcass cooling. The weights of commercial cuts and the weights of total muscle, total bone, intramuscular fat, and total fat decreased linearly. All morphometric measurements were influenced by the inclusion of pineapple stubble hay in the .diets. Substitution of Tifton hay for pineapple stubble hay at the level of 33 g/100 g improves the carcasses of UB goats qualitatively and quantitatively
compactness index; loin eye area; morphometric measurements; subcutaneous fat thickness; waste cultures
Introduction
Goat raising in the Brazilian Northeast is an important economic and social activity, especially for small producers, due to the high adaptability of goats to the soil and climate conditions of the region (Bezerra et al., 2010). The confinement of goats, thus, may be a feasible alternative of raising, especially when it is aimed at intensifying the production system, and improve meat supply and carcassquality (Dias et al., 2008).
Evaluating carcasses, Cartaxo et al. (2011)reported that loin eye area, subcutaneous fat thickness, and marbling are characteristics related to daily weight gain, carcass yield, finishing, meat flavor and juiciness, whereas tissue composition is based on the amount of muscle, and adipose and bone tissues (Monte et al., 2007). Moreover, in countries where meat is sold at retail, the content of each cutis an important factor that determines its value (Mahgoub and Lu, 1998).
According to Hadjipanayiotou (1987), feeding in intensive production systems represents 55 to 75% of the total production costs.Thus, evaluating different diets and their effects becomes essential in production systems.
A strategy to reduce feeding costs is to use agro-industrial by products or regional feeds, particularly roughages, capable not only of perpetuating in the semi-arid region, but also producing large amounts of hay per unit area (Moreira et al., 2008). Among these feeds is pineapple plant debris, which can be consumed by goats in the form of hay. However, little is known about the carcasscharacteristics of animals fed pineapple plant debris.
The objective of this research was to evaluate substitution of Tifton hay for pineapple stubble hay on the characteristics of thecarcasses of goats of an unknown breed.
Material and Methods
Thirty-two bucks of an unknown breed (UB), with an initial weight of 17.5±1.3 kg, at approximately 150 days of age, were used. They were weighed, identified, vaccinated against clostridiosis and dewormed with ivermectin at 1%, and then housed in individual.stalls (0.80 × 1.20 m) provided with feeding and drinking troughs.
The complete diets, supplied twice a day (Table 1), were formulated to meet the nutritional requirements for growth recommended by the NRC (2007), aiming at weight gains of 150 g/day. The experimental period had the duration of 90 days, 14 of which were intended for the adaptation of the animals to environment, handling, and diet. The goats were weighed every 14 days according to the experimental periods.
For the process of preparation of the pineapple stubble hay, the pineapple plants were processed through a forage machine and exposed to the environment for dehydration.
The Tifton hay, of the tifton-85 (Cynodon dactylon) variety, was acquired commercially.
At the end of the experimental period, the animals were deprived of solids for 18 hours, and then weighed to determine their slaughter weight (SW), and subsequently slaughtered.
At slaughter, the animals were stunned by cerebral concussion in the atlas-occipital region, and then suspended by the hind legs, followed by bleeding by severing the jugular veins and carotid arteries. After bleeding and skinning, the gastrointestinal tract (GIT), skin, and viscera were removed. The viscera were weighed, full and empty, to determine the contents of the gastrointestinal tract (GITC); head, legs and genitals were removed.
The empty body weight (EBW) was obtained as the difference between slaughter weight (SW) and gastrointestinal content weight.
The carcasses were weighed to obtain the hot carcass weight (HCW), and then packed in polyethylene bags and stored in a cold.room at 4 ºC, where they remained for 24 h
Once chilled, the carcasses were weighed to obtain the cold carcass weight (CCW). The hot carcass yield (HCY) and cold carcass yield (CCY) were determined with the following formulas: HCY = (HCW/SW) × 100, and CCY = (CCW/SW) × 100. The biological yield (BIOY) was also evaluated, calculated as follows: BIOY (g/100 g) = (HCW/EBW) × 100. The weight loss by cooling (WLC) was determined by the following expression: WLC (g/100 g) = (HCW - CCW/HCW) × 100.
Subsequently, the qualitative characteristics of the carcasses were determined in the refrigerated environment by evaluations of conformation and exterior visual impressions of the carcass and the amount of kidney-pelvic fat.
The carcass conformation was evaluated with emphasis on anatomical regions (leg, rump, loin, shoulder, and their muscles) and the exterior visual impressions of the carcass were performed with emphasis on thickness and distribution of fat in relation to the skeleton according to the categories and scores (1 to 5) demonstrated by Cezar and Sousa (2007), as well as by determining the amount of kidney-pelvic fat. After this procedure, the carcasses were split longitudinally.
To determine marbling, visual examination was performed on the surface of the longissimus dorsi, and scores of 1 to 3 (nonexistent, little, and medium) were given, according to the methodology described by Cezar and Sousa (2007).
A transversal cut was made on the left half-carcass between the 12th and 13th ribs, exposing the transverse cross section of the longissimus dorsi muscle, and the loin eye area (LEA) was determined with the use of clear plastic wrap, by means of which the maximum width (A) and the maximum depth (B) were obtained with a millimeter ruler to determine the area, according to the following formula: LEA = (A/2*B/2) π. Subcutaneous fat thickness (SFT) was measured with a digital caliper and determined by thedepth of fat over the 12th rib.
On the right half-carcass, the length of the inner carcass was measured using a tape measure to calculate the carcass compactness index: CCI = CCW/length of the inner carcass (LIC), according to Yáñez et al. (2004). The leg compactness index (LCI) wasdetermined as the rump width in relation to the leg length.
Then, the following morphometric measurements were performed using a measure tape and a hipometer: chest width, rump width, chest depth, chest circumference, rump circumference, leg circumference, carcass length, inner-carcass length, and leg length,all expressed in centimeters.
After that, the right half carcass was sectioned into five anatomical regions (commercial cuts): neck, shoulder, ribs, loin, and leg, according to the methodology described by Colomer-Rocher (1986). These cuts were individually weighed and quantified inpercentage of the right half-carcass.
The legs were packed in plastic bags, properly sealed and identified, and stored in a freezer at −20 º C for one week.
The tissue composition of the carcass was estimated indirectly, and instead of separating the bones, muscles and fats in the entire carcass, the proportion of these tissues in the leg was used a parameter which holds high correlation with the results obtained with the dissection of the carcass (Piola Junior et al., 2009).
For this purpose, the legs were removed from the freezer, weighed, thawed at 10 ºC for 24 h, and dissected according to the methodology described by Silva Sobrinho (1999), to determine the proportions of muscles, bone, and fat, and subsequent ratios ofmuscle:bone and muscle:fat.
The leg muscularity index (LMI) was determined after dissecting and weighing the five muscles that cover the femur - femoral biceps, semitendinosus, adductor, semimembranosus, and femoral quadriceps and the femur completely cleaned. For such, theformula described by Purchas et al. (1991) was used:
in which P5M is the weight (g) of the five muscles and LF is the length (cm) of the femur.
The statistical design was completely randomized, with four treatments, at levels of substitution of Tifton hay for pineapple stubble hay (0, 33, 66, and 100 g/100 g) and eight replications.
The data were subjected to analysis of variance with polynomial regression, considering the levels of pineapple stubble hay.
For the analyses of variance, two mathematical models were used, in which the initial weights (p) and slaughter weight (SW) were used as a covariate.
(1)Yij = µ + ti + pj + eij,
in which: Yij = observed value of each dependent variable referring to treatment i, in replication j; µ = overall mean; ti = effect of treatment i, i = (1, 2, 3 and 4); pj = effect of the initial weight covariate; and eij = random error associated with each observation.
The initial weight was included as a covariate for the variables of Table 2, except HCY, CCY and BIOY, in which the initial weight covariate (p) was not significant, and was thus removed from the model.
(2)Yij = µ + ti + paj + eij,
in which: Yij = observed value of each dependent variable referring to treatmenti, in replication j; µ = overall mean; ti = effect of treatment i, i = (1, 2, 3 and 4); paj = effect of the slaughter weight covariate; and eij = random error associated with each observation.
The slaughter weight was included as a covariate for the variables of Tables 3, 4, 6 and 7, except for kidney-pelvic fat, marbling (Table 3); leg compactness index (LCI), leg muscularity index (LMI) (Table 4); percentage of leg, loin, rib, shoulder and neck (Table 6); other tissues, percentage of muscle, bone, fat, other tissues, and muscle:bone and muscle:fat ratio (Table 7), in which a covariate slaughter weight (SW) was not significant, and was thus removed from the model.
Results
The substitution of Tifton hay for pineapple stubble hay resulted in a decreasing linear effect (P<0.01) on slaughter weight (Table 2). This may have occurred due to the reduction of the initial weight of the goats as the levels of pineapple stubble hay were increased in the diets, reflecting in the slaughter weight.
Regarding the qualitative characteristics of the carcasses, there was a decreasing linear effect (P<0.01) on conformation, as well as on the exterior visual impressions (Table 3).
This decrease occurred in response to the reduction in slaughter weight and, consequently, the deficient muscular and adipose distribution, decisive parameters in the evaluation of these respective characteristics.
All of the morphometric measurements were influenced by the inclusion of pineapple stubble hay in the diets (Table 4).
Except for the lengths of the carcass and of the leg, which had quadratic effects (P<0.01), the other measurements - chest width, rump width, chest depth, chest circumference, rump circumference, leg circumference, and inner carcass length - decreased linearly.
Despite the decreasing linear statistic results present in most of the morphometric measurements, the treatment with 33 g/100 g seems to be the one that most influenced the morphometry of the animals.
The quadratic behavior (P<0.05) for loin eye area (Table 5) suggested that the goats fed the diet containing levels of substitution close to 33 g/100 g of pineapple stubble hay had a greater quantity of muscle in the carcass.
There was a decreasing linear effect (P<0.05) for the weights of commercial cuts, leg, loin, ribs, shoulder, and neck (P<0.01); however, the percentages of these cuts were not influenced (P>0.05) by the levels of pineapple stubble hay, except for the percentage of neck, which increased linearly (P<0.01) (Table 6).
The weights of total muscle, total bone, intramuscular fat (P<0.01), and total fat (P<0.05) decreased linearly with the substitution of the hays in the diet of the goats, while subcutaneous fat, other-tissues fat, the percentages of muscle, bone, fat, and other tissues,and the muscle:bone and muscle:fat ratios were not influenced (P>0.05) by the diets (Table 7).
Discussion
With the substitution of the hays in the diets (Table 2), the hot-carcass, cold-carcass, and empty-body weights had a quadratic effect (P<0.05) and the losses by cooling had an increasing linear effect (P<0.01).
The hot-carcass, cold-carcass and biological yields were not influenced (P>0.05) by the levels of substitution of Tifton hay for pineapple stubble hay.
It was observed that despite having different values between the significance of slaughter weight and weights of carcass, the values followed the same tendency and were influenced by the empty body weights, which showed quadratic significance following the weights of carcass.
The values for hot and cold carcass weights are within the expected for goats with these breed characteristics, UB, and type of feed utilized, and it is important to stress that good weights were reached for the commercial reality of the Northeast region of Brazil.
Despite not having a significant effect, it was noted that when the animals received the level of 33 g/100 g of pineapple stubble hay in place of the Tifton hay, the hot-carcass, cold-carcass and biological yields resulted in higher numerical values for all of the variables when compared with the other levels. This fact demonstrates that the collection of data interfered with the result of significance and that this level can be recommended for use as part of the roughage for UB goats in feedlot, although a cost analysis is suggested to better verify its efficiency.
It was also noted that cold- and hot-carcass yields as well as biological yield had satisfactory values, since the average of these yields in most animals slaughtered in the northeast region of Brazil is between 35.5 and 50.0 kg/100 kg (Zapata et al., 2001).
Regarding the qualitative characteristics (Table 3), the results are higher than those reported by Garcia et al. (2006), who evaluated the qualitative aspects of carcasses of Anglo Nubian × UB and Boer × UB goats and obtained lower values for conformation (1.5, 2.0, 1.8, and 2.5) and for exterior visual impressions (1.0, 1.0, 1.0, and 1.0), indicating that the goats in this study had values comparable to those of crossbred animals, although this type of evaluation was performed subjectively.
Replacing Tifton hay with pineapple stubble hay did not influence (P>0.05) the kidney-pelvic fat or the marbling of the carcasses of the goats, which presented little marbling, probably due to the energy in the diets, which had an average of 70.25% TDN, and, according to Berchielli et al. (2006), the energy contained in the diet is rapidly deposited in the animal body. In relation to marbling, studies of Cartaxo et al. (2011) state that it is not increased by the diet; however, it is the genotype that is decisive in improving this .characteristic. Therefore, the utilization of only one genotype in this study, i.e., UB, might explain our observations.
According to Furusho-Garcia et al. (2004), the chest depth and the inner-carcass length (Table 4) can be used as indicators of the live weight or the weight of the carcass. Such characteristics have higher values when evaluated in animals with meat production characteristics, which slightly penalizes the animals utilized in this research, which were UB animals.
Researching the qualities of the carcasses of Saanen goats fed a 50:50 roughage:concentrate ratio, Costa et al. (2008)found the morphometric measurements of 55.6 cm for inner-carcass length and 27.4 cm for chest depth, which are higher values than those found in this study. The lower measurements observed for the UB goats were likely because the roughage utilized in their diets, pineapple stubble hay, has an inferior nutritional value to that supplied to the Saanen goats (elephant grass), as well as because of the genetic potential of the breed.
The proportion of muscle in the carcass (Table 5) corroborates reports of Cartaxo and Sousa (2008). Lower results were foundfor loin eye area (7.2 cm2) by Dias et al. (2008), who studied crossbred Anglo Nubian goats with a live slaughter weight of 27.85 kg.
The subcutaneous fat thickness had a decreasing linear effect (P<0.05), demonstrating a greater protection of the carcasses during cooling for the goats fed the lower level of inclusion of pineapple stubble hay in the diet, suggesting smaller losses by cooling, whichwas observed in this study.
Subcutaneous fat thickness has a great importance in both the juiciness of the meat and in the protection of the carcass. This characteristic can be directly influenced by the intake of nutrients by the animals, mainly energy, as well as by breed characteristics, and the reduction of SFT in this research can be explained by the reduction in the intake of total digestible nutrients in the diets aswell as by the type of animal utilized in this study.
Sousa et al. (2009), studying crossbred Anglo Nubian × UB goats with a hot carcass weight of 12.90 kg, found a lower subcutaneousfat thickness (1.0 mm) in relation to that of the UB goats in our study.
The carcass compactness index decreased (P<0.01) linearly with the substitution of Tifton hay for pineapple stubble hay. According to Simela et al. (1999) and Cezar and Sousa (2007), this index can be utilized to evaluate the production of tissues in thecarcasses of animals with a similar live weight.
Researching Boer × Saanen goats slaughtered at an average weight of 33.82 kg, Hashimoto et al. (2007) observed the following mean values: loin eye area of 13.96 cm2, carcass compactness index of 0.25 kg/cm, and subcutaneous fat thickness of 3.04 mm,similar values to those found for the goats studied here.
The results displayed in Table 6 demonstrate that the goats studied here, despite being slaughtered at different weights, had similar percentages of primal cuts. According to Cezar and Sousa (2007), the leg and the loin are the cuts of highest commercial value, the so-called primal cuts or Grade-A cuts, in view their best muscular yield and tenderer meat. When the results for the commercial cuts are demonstrated in absolute values, it is easier to notice the difference between them; however, when these same results are shown in percentage values, this difference is less noticeable, since the values express how much each cut represents of adetermined region of the carcass.
Results higher than those were reported by Ryan et al. (2007) for crossbred Boer goats fed diets with different levels of concentrate (50, 70, and 90 g/100 g) and with an average hot carcass weight of 14.07 kg. They found the leg yield to be between 26.89 and 31.05 g/100 g, and the shoulder to be between 23.01 and 25.82 g/100 g. The genetic composition and the diet of thegoats utilized by these researchers is likely the explanation for these differences.
In general, a decrease in the weights of the leg tissues can be a reflection of the low growth development of the animals with the increase in pineapple stubble hay in the diet, resulting in lighter-weight carcasses. On the other hand, the result obtained for the percentages of muscle, bone and fat indicates that when slaughtered with a body weight between 20.0 and 25.0 kg, the UB goats showedsimilar tissue proportion.
Studying Indigenous goats with a cold carcass weight of 11.02 kg, Tshabalala et al. (2003) found 76.15, 24.59 and 1.26 g/100 g of muscle, bone and fat, respectively. Because of the similarity of the cold carcass weight in that mentioned study to the weights found in this present research (11.68 kg), these results demonstrated that goats of an unknown breed of Northeast Brazil have a lower percentage of muscle (65.70 g/100 g), similar percentage of bone (24.64 g/100 g), and higher percentage of fat (3.38 g/100g).
Conclusions
Substitution of Tifton hay for pineapple stubble hay at the level of 33 g/100 g improves the morphometric, qualitative, and.quantitative characteristics of carcasses of goats of an unknown breed subjected to feedlot finishing
Acknowledgments
The authors thank EMEPA-PB / FINEP for the support and funding of the research project.
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Publication Dates
-
Publication in this collection
Feb 2015
History
-
Received
03 Apr 2013 -
Accepted
28 Aug 2014